Multinuclear NMR studies of molybdenum and tungsten carbonyl

Martin Minelli, and Walter J. Maley ... Mikhail V. Barybin, William W. Brennessel, Benjamin E. Kucera, Mikhail E. Minyaev, Victor J. Sussman, Victor G...
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Inorg. Chem. 1989, 28, 2954-2958

2954

oration of some of the hexane and cooling led to the precipitation of purple crystals. These were filtered to yield 0.7 g (0.57 mmol, 63% yield based on Co) of Cp2Zr[OCCo3(CO)g]2identified by comparison of its NMR and IR spectra with those previously p ~ b l i s h e d . ~ Reaction between Cp2Ti(CO), and C O ~ ( C Oin ) ~THF. Cp,Ti(CO),, 0.50 g (2.14 mmol), was dissolved in SO mL of THF. CO,(CO)~,0.36 g (1.07 mmol), was added as a solid to the above solution, and gas evolution was noted by foaming of the reaction mixture. Infrared analysis of the reaction mixture indicated, in addition to bands due to C O ~ ( C O ) ~ , a very strong absorption at 1890 cm-I, indicative of the Co(C0); species. The solution was stirred at room temperature for 3 h. Pentane was slowly added to the reaction mixture to precipitate 0.65 g (1.32 mmol, 62% yield) of a blue-green crystalline solid identified as [Cp2Ti(THF),] [Co(CO),] on the basis of the following information. IR (THF solution): 1890 cm-l. IR (toluene solution): 2010, 1915, 1750 cm-l. Due to the lability of the T H F molecules, a satisfactory elemental analysis could not be obtained. However, the single-crystal X-ray structure did confirm the composition! Reaction between (Cp2TiCl), and TICo(CO),. (Cp,TiCl),, 1.0 g (2.34 mmol), was dissolved in 75 mL of THF, and the TICo(CO), (1.76 g, 4.68 mmol) was added as a solid. The reaction mixture was stirred at room temperature for 18 h, at the end of which time there was a white precipitate of TICI. The mixture was filtered, and the blue-green filtrate was diluted with pentane to precipitate 1.5 g (3.03 mmol, 65%) of a blue-green crystalline solid identical in all respects with the material synthesized from Cp,Ti(CO), and C O ~ ( C Odescribed )~ above. Reaction between Cp*,Ti(CO), and C O ~ ( C Oin ) ~ Hexane. Cp*,Ti(CO),, 0.5 g (1.34 mmol), was dissolved in SO mL of hexane and the solution filtered to remove any insoluble material. Likewise, CO,(CO)~, 0.46 g (1.34 mmol) was dissolved in 50 mL of hexane and the solution filtered. The two solutions were combined, stirred, and then allowed to stand undisturbed. After about 1 h, crystal formation was evident. After 18 h, the mixture was filtered and 0.31 g of a green, crystalline solid was isolated. After 48 h, an additional 0.24 g of product was isolated. The total yield was 0.55 g (1.12 mmol, 83% yield) of [Cp*,TiOCCo(CO),],, identified on the basis of the following data. Anal. Found (calcd for C24H30C004Ti):C, 58.3 (58.9); H, 5.81 (6.19); Ti, 9.97 (9.79); Co, 11.87 (12.04). IR (vm, Nujol mull): 2020 (m), 1942 (s), 1835 (m) cm-l. An attempt was made to obtain the X-ray crystal structure of this complex.s Due to poor crystal quality the structure was not able to be refined completely, but the dimeric nature of this complex was confirmed. Reaction between Cp*,Ti(H2C=CH2) and C O ~ ( C O )in~ Hexane. Cp*,Ti(H2C=CH2), 0.20 g (0.59 mmol), was dissolved in 50 mL of

hexane. C O ~ ( C O )0.20 ~ , g (0.58 mmol), was added to the solution. A green precipitate formed immediately. The precipitate was filtered out, washed with hexane, and dried to yield 0.22 g (0.45 mmol, 78% yield) of [Cp*2TiOCCo(CO),]2, identical with the material formed by using Cp*,Ti(CO), as starting material. Reaction between Cp*,Ti(CO), and C O ~ ( C Oin ) ~Toluene. Cp*,Ti(CO),, 0.5 g (1.34 mmol), was dissolved in 50 mL of toluene. To the ) ~a solid. above solution was added, 0.23 g (0.67 mmol) of C O ~ ( C Oas An infrared spectrum of the reaction solution at this point indicated that all of the C O ~ ( C Ohad ) ~ been consumed with a significant portion of the Cp*,Ti(CO), remaining, so an additional 0.23 g of CO,(CO)~was added. The reaction mixture was stirred for 18 h. The solvent was removed under reduced pressure, and the residue was washed with hexane, leaving 0.66 g (1.0 mmol, 75% yield) of Cp*2Ti[OCCo(C0),]2, identified on the basis of the following information. Anal. Found (calcd for C28H30C0208Ti):C, 51.33 (50.92); H, 4.41 (4.59); Co, 17.40 (17.85); Ti, 7.71 (7.25). IR (vc0, Nujol mull): 2050 (s), 1850 (m) cm-l. 'H NMR (e&,): 6 1.67 ppm. Thermolysis of C~,T~[OCCO,(CO)~]~. C ~ , T ~ [ O C C O , ( C O )1~.O] ~g (0.9 mmol), was dissolved in SO mL of xylene, and the solution was heated to reflux for 4 h. The reaction mixture was cooled, and the xylene was removed at reduced pressure. The residue was extracted with hexane, and the hexane was removed to yield 0.21 g of a dark red oil, identified as C ~ C O ( C Oby ) ~comparison of its IR and NMR spectra with those of an authentic sample. Based on the number of available Cp rings in the system, this represents a 64% yield of C ~ C O ( C O ) The ~ . hexaneinsoluble material was not characterized. Reaction between [Cp,Ti(THF),XCo(CO),] and PPh, in Toluene. [Cp2Ti(THF),][Co(C0),], 0.5 g (1.01 mmol), was dissolved in 60 mL of toluene. To this solution was added 0.34 g (1.34 mmol) of PPh3 as a solid. The solution immediately changed from green to red-brown, and after 10 min, a red-brown precipitate had formed. The mixture was allowed to stir for 3 h, and then it was filtered to collect 0.26 g (0.32 mmol, 64% yield based on Co) of CO,(CO)~(PP~,),, identified by comparison of its IR spectrum with that of authentic material. An infrared spectrum of the filtrate showed only absorptions due to Cp2Ti(C0),. Reaction between Cp2Ti[OCCo3(C0)9]2and PPh,. Cp2Ti[OCCo3(C0)9]2r0.30 g (0.33 mmol), was dissolved in SO mL of toluene. To this solution was added, O S g (1.9 mmol) of PPh, as a solid. After a few minutes, a red-brown solid precipitated from solution. This solid was collected, washed with hexane, and dried to yield 0.65 g (0.8 mmol, 81% yield based on Co) of c ~ ~ ( c o ) ~ ( P P hInfrared , ) ~ . analysis of the solution showed only the presence of of Cp,Ti(CO),.

Contribution from the Department of Chemistry, Grinnell College, Grinnell, Iowa 501 12

Multinuclear NMR Studies of Molybdenum and Tungsten Carbonyl Isocyanide Complexes' Martin Minelli* and Walter J. Maley Received January 17, 1989 M(CO),,(CNR), ( n = 0-6) complexes (M = Mo, W; R = 2,6-dimethylphenyl, tert-butyl, cyclohexyl, isopropyl) have been synthesized. Depending on the R group of the isocyanide ligand, four or six carbonyl groups in M(C0)6 can be replaced. The NMR properties of the atoms in these complexes have been studied. The metal centers, observed by gsMo or In3WNMR, show increased deshielding with the substitution of carbonyl ligands by isocyanide ligands. 95MoNMR serves as an excellent tool for the identification of mixtures of these compounds and was useful to monitor the reactions. The nitrogen in the isocyanide ligand, observed by I4N NMR spectroscopy, gets more deshielded when the isocyanide is coordinated to the metal center, but with further substitution, the nitrogen becomes more shielded again. The I4N chemical shift of an isocyanide ligand trans to a carbonyl ligand differs slightly from the chemical shift of an isocyanide ligand trans to another isocyanide ligand in the tetrasubstituted complex. The I3C NMR signal of the CNR carbon becomes more deshielded with an increasing number of isocyanides present in the complex. CNR carbons trans to carbonyl groups are more shielded than CNR carbons trans to isocyanides. With the successive substitution of carbonyl groups by isocyanides, the electronic absorption bands in the UV-vis region shift toward longer wavelengths; Le., the color of the compounds changes from white to orange-red.

Introduction A number of papers have been published containing 13C,*s3 14N,4*5 or "OsNMR d a t a on molybdenum(0) and tungsten(0)

carbonyl isocyanide complexes. T h e d a t a available so f a r a r e limited to mono- to trisubstituted complexes, and no NMR data for the metal nuclei in these complexes have been published. Albers a n d c o - w o r k e r ~discovered ~~~ a convenient route to

(1) Presented in part at the 3rd International Chemical Congress of North

America, Toronto, Canada, June 1988.

(2) Cronin, D. L.; Wilkinson, J. R.;Todd, L. J. J . Mugn. Reson. 1975, 17, 353. (3) Dombek, B. D.; Angelici, R. J. J . Am. Chem. SOC.1976, 98, 4110.

0020-1669/89/ 1328-2954$01.50/0

(4) Becker, W.; Beck, W.; Rieck, R. Z.Nuturforsch. 1970, 25B, 1332. ( 5 ) Guy, M. P.; Coffer, J. L.; Rommel, J. S.; Bennett, D.W. Inorg. Chem. 1988, 27, 2942. (6) Coville, N. J.; Albers, M. 0. Inorg. Chim. Acta 1982, 65, L7.

0 1989 American Chemical Society

Mo(CO),-,(CNR),, and W(CO),-,(CNR), Table I. Elemental Analyses compd

%C

M ~ ( C O ) ~ ( d m p i ) ~67.45 " M ~ ( C O ) ( d m p i ) ~ 70.85 MO(dmpi)6 73.44 Mo(CO),(cyhi), 61.22 M 0 ( C 0 ) ~ ( i p i ) ~ 50.46 Mo(CO),(tbui), 54.53 W(CO)2(dmpi)4 59.69 W(CO)(dmpi)c 63.67 . W(dmpi)6 66.80 This sample contained

-

Inorganic Chemistry, Vol. 28, No. 15, 1989 2955 Table 11. 95MoNMR Chemical Shifts"

calcd %H 5.36 5.82 6.18 7.54 6.60 7.50 4.75 5.23 5.61

found %N %C %H %N 1.92 8.28 65.85 5.40 8.92 8.98 70.76 5.85 9.51 9.52 73.35 6.19 9.02 9.56 59.49 7.43 13.08 49.62 6.46 12.70 11.56 54.41 7.56 11.52 7.02 7.32 58.35 4.81 8.17 8.07 63.62 5.49 8.65 66.68 5.62 8.63

10% trisubstituted product.

chem shift, ppm Rcompd tert-butyl Mo(C0)SCNR -1850 cis-Mo(CO),(CNR), -1825 ~ ~ C - M O ( C O ) ~ ( C N R -1783 ), cis-Mo(C0)2(CNR)4 -1 7 16 Mo(CO)(CNR)S Mo(CNR)~ a

R= R= R= 2,6-dimethylisopropyl cyclohexyl phenyl -1850 -1853 -1 848 -1825 -1831 -1825 -1784 -1793 -1786 -1 726 -1 729 -1715 -1626 -1525

Reference 2 M Na2Mo04in D20, basic; solvent CH2C12.

Table 111. 13C and 14N NMR Chemical Shifts for Isocyanide

synthesize M(CO),,(CNR), ( n = 0-6) complexes by using PdO Ligands as a catalyst. With this method, we were able to obtain a complete chem shift, ppm series of molybdenum and tungsten complexes for N M R studies. 1 4 ~ b Within the last few years, multinuclear N M R has become a ligand "C" (CNR) (CNR) ref valuable tool for the characterization and identification of tranmethyl isocyanide -218 (8) 4, 23 sition-metal compounds. Atoms in different parts of the molecule ethyl isocyanide 4, 23 -203 (8) can be observed. N M R spectra of metal nuclei provide an exisopropyl isocyanide 153.5 (4.8) -194 (10) this work cellent tool to study the metal centers directly. It has been shown n-butyl isocyanide 155.4 (5.1) -210 (10) this work with 95MoNMR, for example, that small changes in the coortert-butyl isocyanide 152.4 (4.5) -186 (10) this work dination sphere cause pronounced changes in the NMR chemical cyclohexyl isocyanide 153.8 (5.3) -197 (10) this work shift of the metal centere8 The replacement of a hydroxy oxygen benzyl isocyanide 157.4 (4.7) -212 (10) this work by a mercapto sulfur in an otherwise identical complex causes 2,6-dimethylphenyl isocyanide 167.7 (6.2) -206 (10) this work 156.4 (5.6) -211 (15) this work deshielding of the molybdenum nucleus by about 200 ~ p m . ~ morpholinoethyl isocyanide Geometric isomers and diastereomers can also be distinguished " In CDCI,; triplet, coupling constant in Hz in parentheses. quite easily.I0 Multinuclear N M R spectroscopy can replace or bReference nitromethane, neat; line width in Hz in parentheses; solvent complement other methods to characterize compounds. N M R CH2C12. data that show the effect of the complete exchange of one ligand by another in two-ligand complexes are rare. In this work we used 95Mo, 183W,I4N, and I3C N M R spectroscopy to observe the M(C0)5L chemical shift changes that occur in different parts of the molecule when the carbonyl ligands in M(C0)6 are sequentially replaced by isocyanide ligands. Experimental Section All experiments were performed under argon, the solvents were dried and distilled prior to use, and the products were stored at -5 'C in a drybox. Cyclohexyl (cyhi), tert-butyl (tbui), and isopropyl isocyanides (ipi) were purchased from Strem Chemicals, 2,6-dimethylphenyl isocyanide (dmpi) was purchased from Fluka, palladium(I1) oxide, and hexacarbonylmolybdenum(0) and hexacarbonyltungsten(0) were purchased from Aldrich. The ligands, the palladium(I1) oxide, and the metal hexacarbonyls were used without further purification. The molybdenum and tungsten complexes were synthesized according to the method of Albers et aL6v7by refluxing the metal hexacarbonyl with the appropriate equivalents of ligand in toluene with PdO used as catalyst. The tetra-, penta-, and hexasubstituted complexes were also synthesized with M(CO)6 (M = Mo, W) and the corresponding equivalents of ligand, not with M(CO),(CNR), as described in ref 6. The crude products were recrystallized in a hexanes/dichloromethane mixture. For molybdenum, the mono- to trisubstituted complexes were refluxed for 10 minutes, the tetrasubstituted compounds were obtained after refluxing from 15 min (dmpi) to 19 h (tbui). The pentasubstituted complex (dmpi) was refluxed for 1.5 h and the hexasubstituted complex (dmpi) for 2 h. In the reactions with cyhi, tbui, and ipi, no more than four carbonyl groups could be replaced with isocyanides. The reaction times for the tungsten complexes were significantly longer. The mono- to trisubstituted compounds were refluxed for several hours; the tetrasubstituted complex was refluxed for 1 day, the pentasubstituted complex for 2 days, and the hexasubstituted complex for 4 days. The identities of the mono- to trisubstituted complexes were confirmed by comparing the IR and 13CNMR data with the literature data; the (7) Albers, M. 0.;Singleton, E.; Coville, N. J. J . Chem. Educ. 1986, 63, 444. (8) Minelli, M.; Enemark, J. H.; Brownlee, R. T. C.; O'Connor, M. J.; Wedd, A. G. Coord. Chem. Reu. 1985, 68, 169. (9) Christensen, K. A,; Miller, P. E.; Minelli, M.; Rockway, T. W.; Enemark, J. H. Inorg. Chim. Acta 1981, 56, L27. (10) (a) Minelli, M.; Rockway, T. W.; Enemark, J. H.; Brunner, H.; Muschiol, M. J . Organomet. Chem. 1981, 217, C34. (b) Brunner, H.; Beier, P.; Frauendorfer, E.; Muschiol, M.; Rastogi, D. K.; Wachter, J.; Minelli, M.; Enemark, J. H. Inorg. Chim. Acto 1985, 96, L5.

fac-M(C0) 3L3

1' T CN cl"

ML6

I

-I

I

I

I

I

2200 2100 2d00 1800 Figure 1. IR frequency diagram for M(CO),CNRb, complexes (M = Mo, W) according to ref 6. identities of the tetra- to hexasubstituted complexes were established by elemental analysis (Table I). IR spectra were measured on a Nicolet 5XSB FT-IR spectrometer in a NaCl IR solution cell. CH2CI2was used as solvent. The NMR spectra were measured on an IBM N R 300-MHz NMR spectrometer. For the 13C N M R spectra, a 5-mm dual IH/l3C probehead was used, I4N and 95MoNMR spectra were measured on a IO-mm broad-band probehead (IWAg-,lP) with digital tuning, and the ls3W NMR spectra were obtained with a standard selective tungsten probehead. For the 13C NMR spectra the solvent, CDC13, was used as an internal reference; for the other nuclei external standards were used as references: I4N,nitromethane, neat; 95Mo,2 M Na2Mo04in D20,basic; IS3W,saturated Na2W04in D20, basic. The concentrations of the solutions were about 0.1 M except for 18)W N M R measurements, where generally higher concentrations or saturated solutions were used. The electronic spectra were measured on a Beckman 5260 spectrophotometer.

2956 Inorganic Chemistry, Vol. 28, No. 15, 1989

Minelli and Maley

Table IV. I4N NMR Chemical Shifts"

chem shift, ppm R = 2,6-dimethyl-

compd Mo(CO)&NR cis-M~(co)~(CNR)~ ~uc-Mo(CO),(CNR), c~s-Mo(CO)~(CNR)~

R = terr-butyl -180 (10) -182 (20) -184 (30) -183 (90) -187 (70)

R = isopropyl -188 (20) -190 (20) -193 (30) -193 (50) -194 (40)

R = cyclohexyl -191 (20) -193 (20) -196 (40) -196 -198'

(50) (80) (100) (200)

W complex (R = dmp) -202 (30) -203 (80) -203 (100) -206 (200)

-203 (330) -197 (350)

-197 (420) -197 (500)

phenyl (dmp) -200 -202 -202 -196

Mo(CO)(CNR), Mo(CNR)~

"Samples in CH2CI2;reference nitromethane, neat; line widths in Hz in parentheses. bPeaks not separated well enough to determine line widths Table V. 13C NMR Data"

chem shift. mm OC-M-CO Mo W

compd

M(C0)6 201.6 M(CO)dCNR) 203.6 C ~ ~ - M ( C O ) ~ ( C N R ) ~ 206.0 fac-M(CO)j(CNR)p C~S-M(CO)~(CNR)~ M(CO)(CNR)s M(CNR)6

" In CDCI,;

OC-M-CNR Mo W

191 194.0 196.7

206.5 209.5 212.2 215.0 217.1

OC-M-CNR Mo W

196.4 199.8 202.7 205.7 208.3

165.7 169.8 173.6 177.1 180.5

RNC-M-CNR Mo W

155.1 159.5 163.6 167.5 171.0

181.0 184.8 185.0

170.9 175.1 175.5

R = 2,6-dimethylphenyl.

Table VI. I3C NMR Data"

OC-M-CO R2b 201.64 MO(CO), Mo(CO)S(CNR) 203.9 203.9 c ~ ~ - M o ( C O ) ~ ( C N R )206.6 ~ 206.5 ~uc-Mo(CO)~(CNR)~ C~~-MO(CO)~(CNR)~

comvd

Rlb

OC-M-CNR R2

R3b

R1

203.9 206.6

207.1 21 1.0 214.3 217.6

206.5 210.8 213.9 217.0

OC-M-CNR R2

R3

R1

207.0 210.7 213.9 217.2

149.9c 154.4' 158.8 163.7

150.9c 154.7c 158.7 163.1

RNC-M-CNR R2 R3

R3

R1

151.2c 155.9c 159.9 164.1

173.3

170.8

171.6

"in CDCI,. bR1 = tert-butyl, R2 = isopropyl, R3 = cyclohexyl. 'Triplet. Results The data obtained in this work are presented in Tables I-VI, and Figure 1. Tables 11-VI and Figure 1 are introduced at appropriate points in the section that follows. Discussion Synthesis. With the ligands used in this work, complete substitution of six carbonyl ligands in M(C0)6 to form M(CNR)6 was only possible with dmpi, a ligand with an aryl R group. The other isocyanides with aliphatic R groups (cyhi, tbui, ipi) only replaced up to four carbonyl groups. Isocyanide ligands are considered to be more basic than carbonyl ligands. They are also slightly weaker a-acceptors than carbonyl ligands2 and therefore donate more electron density to the metal center. With an aromatic R group participating in the metal to ligand a-bonding, enough electron density is removed from the metal to allow complete substitution. The aliphatic R groups cannot particpate in the metal to ligand r-bonding, and therefore, not enough electron density is removed to allow complete substitution. When the isocyanide ligand is introduced into the carbonyl complex, the metal-carbon bond of the carbonyl group trans to the isocyanide ligand is strengthened. As a result of this only cis andfac isomers are isolated. The CO stretching frequencies in the IR spectrum are lowered as expected (Figure 1). Even though stoichiometric amounts of starting material were used for the syntheses of all complexes, mixtures instead of pure products were frequently obtained, especially for the higher substituted compounds. It was quite difficult to monitor the progress of the substitution by infrared spectroscopy since both the CO and the CN stretching frequencies occur in the same region and overlap. We therefore tried to use N M R spectroscopy to identify the reaction mixtures. For the molybdenum compounds 95MoN M R was a good method to monitor the reactions. The line widths of the Mo(CO),,(CNR), compounds are narrow,

.067

4

CM-'

-1500

-1600

-1700

-1800

-1900 (PPMI

Figure 2. Mixture of Mo(CO)~(CNR)~ and Mo(CO)(CNR), in CH2CI2: (a) IR spectrum; (b) 95MoNMR spectrum.

around 10 Hz,and spectra are obtained rapidly. Figure 2a shows the IR spectrum of a reaction mixture and Figure 2b shows the 95MoNMR spectrum of the same solution. The IR spectrum does not allow an immediate identification of the compounds in solution whereas the 95Mo N M R spectrum shows the presence of two

Mo(CO),-,,(CNR), and W(CO)+,,(CNR),

Inorganic Chemistry, Vol. 28, No. 15, 1989 2957

where np and nd refer to the valence p and d electrons, P,,and species, M ~ ( C O ) ~ ( d m p iand ) , Mo(CO)(dmpi),. D, represent the electron imbalance about the nucleus, and AE Using molybdenum N M R to monitor the reactions, we were is the average electronic excitation energy. With an increasing able to obtain pure products. The reaction times for the tetranumber of isocyanide ligands the color of the complexes changes to hexasubstituted compounds were significantly shorter than from white to orange-red; Le., AE becomes smaller. This causes indicated in the literatures6 Refluxing a stoichiometric mixture the paramagnetic shielding term, which has a negative sign, to for the hexasubstituted dmpi complex yielded the product after become larger, and the shielding decreases. The relationship 2 h compared to 24 h suggested in the literature. When the between the A,, of the complexes and the 95MoN M R chemical reaction mixture is refluxed longer, the product peak in the NMR shifts for this series is not linear. We have no data to estimate spectrum decreases again. During the synthesis of the pentathe values of P, or D,, and therefore, the contributions of P,, D,,, substituted dmpi complex, even though stoichiometric amounts and AE to give the observed chemical shift cannot be determined. of the reactants were present, some hexasubstituted complex was I8jW NMR. For the tungsten compounds I8,W N M R was not formed as well. a convenient method to identify reaction mixtures since the re95Mo NMR. The 95Mo N M R chemical shift range of the ceptivity of I8jW is about 50 times lower than that of 95M0.21 molybdenum carbonyl isocyanide compounds stretches from -1 856 Long relaxation delays between pulses are necessary for the data (Mo(CO),) to -1525 ppm (Mo(dmpi),) (Table II), a region acquisitions from this dipolar nucleus, whereas no relaxation delays typical for Mo(0) compounds.8 The molybdenum center is deare necessary for the quadrupolar g5Monucleus. 13CN M R was shielded with each substitution. The first isocyanide causes deused for a first identification of the tungsten products. Without shielding of only 3-8 ppm. With further substitution the dea fast method to determine the products in the reaction mixture, shielding increases, up to 101 ppm for the last step. An almost the reaction times could not be determined accurately. They were identical deshielding pattern of the 9SMonucleus was found for significantly longer than those for molybdenum (Experimental Mo(CO)~,,(P(OM~),),(n = 0-6) compounds,8,11-16 the only other Section). complete series with two monodentate ligands studied so far. In Reproducible I8jW N M R spectra were only obtained for the an early 95MoN M R paper," a chemical shift of -1752 ppm and and hexasubstituted complexes in CDCl, (W(CO)(dmpi)5, a line width of 130 Hz were reported for M O ( C O ) ~ ( C N M ~ ~ P ~penta) -3139 ppm; W ( d m ~ i ) -2918 ~, ppm). W(CO), has a chemical in CDCl,. According to our data, this value cannot be correct shift of -3486 ppm in CH2C12.24 These data show that the I8jW since all the monosubstituted complexes show deshielding of less nucleus like the 95Monucleus becomes more deshielded with an than 10 ppm when compared to Mo(CO), (CNMe2Ph probably increasing number of isocyanide ligands present. The chemical is dmpi). shift ratio of 183W/95Mo is 1.9. Ratios of this order are generally The line widths of the 95MoN M R signals are about 10 Hz. found when 18jWand 95MoNMR chemical shifts are compared.8 For the penta- and hexasubstituted dmpi complexes, line widths No 18jW N M R data are in the literature for higher substituted of 20 and 40 Hz are observed, probably due to an increase in the compounds except for tr~ns-W(C0)~(P(OMe),)~ (-3207 ppmI4). correlation time, T ~ . I4N NMR. The isocyanide nitrogens are easily observed by I4N The R group of the isocyanide ligand does not have a large NMR. They absorb around -200 pprn (Table III).4*22923There effect on the 95MoNMR chemical shift. The cyhi complexes with is a certain amount of confusion in the 14Nliterature concerning the largest aliphatic R group are slightly more shielded than the the chemical shift values. Different references with varying other compounds. standard concentrations are used. Some authors give a positive The deshielding of the 95Monucleus by the isocyanides is small chemical shift sign to compounds that absorb downfield from the compared to that by other ligands. When two carbonyl groups reference; others assign a negative chemical shift sign in the same in M o ( C O ) ~are replaced by other monodentate ligands to form situation. We follow here the procedure used for most nuclei that M O ( C O ) ~ Ldeshielding ~, of 3 1 ppm is found for dmpi, 29 ppm for trimethyl p h ~ s p h i t e , ' ~300 , ' ~ ppm for triphenylph~sphine,'~J~ chemical shifts upfield from the reference have a negative sign and chemical shifts downfield from the reference have a positive 549 ppm for acetonitrile,I2 and 805 ppm for pyridine." The sign. largest deshielding of 826 pprn is achieved with a bidentate ligand, The isocyanide nitrogen becomes deshielded by 6 ppm when 2-phenylazopyridine (2-pap).I8 The Mo(2-pap), complex has one ligand is coordinated to molybdenum (Table IV). The dethe most positive chemical shift known to date for a Mo(0) shielding is only 4 ppm in the tungsten analogue. Upon further complex, +1502 ppm. substitution, the nitrogen becomes more shielded, but the chemical For a theoretical understanding of the chemical shifts the shift changes are minimal compared to those of the metal centers. Ramsey equation ( u = ad + up), which separates the shielding, For the tetrasubstituted complexes, two distinct peaks are observed, u, into a diamagnetic (ud) and a paramagnetic (cP) term, is 1-4 ppm apart, for the two different environments of the isocyanide generally used.I9 The paramagnetic term is the dominant factor ligands, trans to CO and trans to each other. No two peaks could in heavy nuclei such as 9sM020 be distinguished for the dmpi complexes because of the larger line UP = (-fi0e2h2/6nm2AE)( (F3),,,P,,+ (f3),,,jDP) widths. The shielding pattern can also not be seen as clearly in the dmpi complexes. This may be due to the aromatic R group, (11) Dysart, S.; Georgii, I.; Mann, B. E. J . Organomet. Chem. 1981, 223, but the precision of the chemical shift values also decreases with c10. increasing line widths ( f 3 ppm for line widths from 200 to 500 (12) Alyea, E. C.; Somogyvari, A. In Proceedings of the Climax Fourth Hz8). In [MO(CNR),]~+complexes the isocyanide nitrogen is International Conference on the Chemistry and Uses of Molybdenum; Barry, H. F., Mitchell, P. C. H., Eds.; Climax Molybdenum Company: considerably more deshielded (-1 56 ppm, R = t e r t - b ~ t y l ) . ~ ~ Ann Arbor, MI, 1982; p 46. Bennett and co-workers, who recently published I4N data for (13) Alyea, E. C.; Lenkinski, R. E.; Somogyvari, A. Polyhedron 1982, 130, the mono- to trisubstituted tungsten complexes with one aliphatic 1. ligand, tert-butyl isocyanide, and one aromatic ligand, p-tolyl (14) Andrews, G . T.; Colquhoun, I. J.; McFarlane, W.; Grim, S. 0.J . Chem. SOC.,Dalton Trans. 1982, 2353. isocyanide, found the same trend for their c o m p o ~ n d s .They ~ (15) Jaitner, P.; Wohlgenannt, M. Monafsh. Chem. 1982, 113, 699. claim that the I4Nnucleus in an aryl isocyanide complex is 14-18 (16) Masters, A. F.; Bossard, G . E.; George, T. A.; Brownlee, R. T. C.; ppm more shielded than that in an alkyl isocyanide complex. A O'Connor, M. J.; Wedd, A. G. Inorg. Chem. 1983, 22, 908. ~

~~

(17) Brownlee, R. T. C.; O'Connor, M. J.; Shehan, B. P.; Wedd, A. G. J. Magn. Reson. 1985, 61, 516. (18) Ackermann, M. N.; Barton, C. R.; Deodene, C. J.; Specht, E. M.; Keill, S. C.; Schreiber, W. E.; Kim, H. Inorg. Chem. 1989, 28, 397. (19) (a) Ramsey, N. F. Phys. Reu. 1950, 77, 567; 1950, 78, 699. (b) Jameson, C. J.; Gutowsky, H. S. J . Chem. Phys. 1964, 40, 1714. (c) Griffith, J. S . ; Orgel, L. E. Trans. Faraday SOC.1957, 53, 601. (20) Nakatsuji, H.; Kanda, K.; Endo, K.; Yonezawa, T. J . Am. Chem. SOC. 1984, 106, 4653. Kanda, K.; Nakatsuji, H.; Yonezawa, T. Ibid. 1984, 106, 5888.

(21) Brevard, C.; Granger, P. Handbook of High Resolution Multinuclear NMR; Wiley-Interscience: New York, 198 1. (221 ,_-,Mason. . .__ - .., J. - ChPm. - - . -Rr. 1983.654. -(23) Witanowski, M. Tetrahedron 1967, 23, 4299. (24) Keiter, R. L.; Van der Gelde, D. G. J . Organomet. Chem. 1983, 258, c34. (25) Minelli, M.; Enemark, J. H.; Bell, A,; Walton, R. A. J . Organomet. Chem. 1985, 284, 25.

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Minelli and Maley

2958 Inorganic Chemistry, Vol. 28, No. 15, 1989 comparison of the 14Nchemical shifts of several isocyanide ligands (Table 111) shows that ligands with aliphatic R groups such as methyl, ethyl, n-butyl, or morpholinoethyl isocyanide have chemical shifts equal to those with aromatic R groups. The I4N chemical shifts do not change significantly after coordination, and the magnitude of the change is only slightly influenced by the nature of the R group. The line widths of the 14N N M R signals increase with an increasing number of isocyanide ligands in the complex. This increase can be correlated with the size of the R group. For a quadrupolar nucleus, the line width, AvIl2, can be expressed asz6 AVI/Z = (TT~,)-’ = ( 3 ~ / 1 0 ) ( 2 Z + 3/12(2Z - l))(e2q,,Q/h)2(1 + s 2 / 3 ) ~ , where Q is the nuclear quadrupole moment, q the local electric field gradient, and t) the asymmetry parameter for q (7 = (qyy - qxx)/qrr).More ligands with large R groups increase the correlation time, T,, which is directly proportional to the line width. The effect is smaller for the 95Mo nucleus, where a significant increase in the line width is only observed for the penta- and hexasubstituted complexes. 13C NMR. The 13C N M R spectra show that the carbonyl carbons trans to another carbonyl group are deshielded by about 3 ppm, respectively, when the first and second isocyanide are coordinated (Tables V and VI). Carbonyl groups trans to isocyanide ligands are deshielded by about 3-4 ppm compared to the carbonyl groups trans to each other in the same complex. These carbons are also deshielded by about 3 pprn with each substitution. The 13CN M R signal of the CNR carbon is split into a triplet by nitrogen. The coupling constants range from 4.5 to 6.2 Hz (Table 111). When coordinated to the metal, the CNR carbon becomes shielded by 2-3 ppm in the Mo complexes and by about 12 ppm in the W complexes (Tables V and VI). Each subsequent substitution deshields by 3-4 ppm. The C-NR coupling constants increase from 5 Hz in the free ligand to about 16 Hz in the monosubstituted complex. In the disubstituted complex, coupling constants around 14 Hz are found. These values agree with those reported for M ~ ( C O ) ~ ( c y hand i ) M~(CO)~(cyhi), earlier.2 For the trisubstituted and higher substituted complexes and for all dmpi complexes, no coupling was observed. The tetrasubstituted complexes show two CNR I3C N M R signals, 4-10 ppm apart, one for isocyanide trans to isocyanide and the other for isocyanide trans to carbonyl. Comparing the peak intensities of the tetrasubstituted dmpi complex with the pentasubstituted dmpi complex allows the assignment of the more shielded peak to the isocyanide trans to the carbonyl group. The CNR carbons bound to tungsten are generally 10 ppm more shielded than those bound to molybdenum.2 In the hexasubstituted complexes the CNR I3C NMR signals are less deshielded and have broader line widths. In isocyanides with aliphatic R groups, the I3C N M R signal of the CNCR’ carbon (R’ = R group without the carbon attached (26) (a) Abragam, A. The Principles of Nuclear Magnetism; Oxford University Press, London, 1961, 314. (b) Harris, R. K. In N M R and

the Periodic Table; Harris, R. K., Mann, B. E., Eds.; Academic Press: London, 1978; p 17.

to the nitrogen) is also split into a triplet by nitrogen. The coupling constants are 5.1 Hz for tbui, 5.3 Hz for cyhi, and 5.8 Hz for ipi. These values are similar to the coupling constants found for the CNR carbons. When the first isocyanide with an aliphatic R group is bound to the metal, the CNCR’ carbon becomes deshielded by about 3 ppm. As the number of isocyanide ligands increases, the CNCR‘ carbons become more shielded in increments smaller than 0.5 ppm. This parallels the trend found for nitrogen, and is contrary to the trend observed for the CNR carbon. While the C-NR coupling constants increase from 5 to 16 Hz, when the first isocyanide is coordinated, the CN-CR’ coupling constants remain almost unchanged, 5.3 Hz for tbui, 4.7 Hz for cyhi, and 5.8 Hz for ipi. No splitting of the I3C N M R CNCR’ peak by nitrogen is detected in the disubstituted and higher substituted complexes. Chemical shift changes of 1 ppm or less are observed for the other carbons in the aliphatic R groups when the number of isocyanide ligands in the complex increases. Two peaks are observed for each carbon in the tetrasubstituted complexes. The CNCR’ carbon in dmpi is deshielded by less than 0.5 ppm when the ligand is bound to Mo or W. With subsequent substitution the CNCR’ carbon becomes more shielded as seen for the aliphatic carbons. No CN-CR’ coupling was observed for the free or coordinated ligand. In the benzyl isocyanide I3C NMR spectrum, no splitting of the CNCR’ carbon was detected either. All dmpi carbons show two peaks in the tetrasubstituted compounds. Small side peaks are observed in the pentasubstituted complexes for the dmpi trans to CO. Conclusions

When the carbonyl groups in M(CO)6 are successively replaced by isocyanide ligands, the following points are observed. (a) The metal centers are increasingly deshielded. (b) The carbonyl carbons are deshielded by 3 ppm with each substitution. The carbon of a carbonyl group trans to an isocyanide is deshielded by 3 ppm compared to the carbon of a carbonyl group trans to *another carbonyl group. (c) The CNR carbons, which are shielded upon coordination, are deshielded by 3-4 ppm with each substitution. CNR carbons from an isocyanide trans to a carbonyl group are more shielded than those trans to another isocyanide. The C-NR coupling constants increase from 5 Hz in the free ligand to 16 Hz in the monosubstituted and 14 Hz in the disubstituted complex. No splitting was observed for higher substituted or dmpi complexes. (d) The isocyanide nitrogen, which is deshielded upon coordination, becomes slightly more shielded again. (e) The CNCR’ carbon, which is initially deshielded by 3 ppm, becomes more shielded. Coupling constants around 5 H z are observed in the free ligands and the monosubstituted complexes. No coupling was observed for dmpi, and the initial deshielding in the molybdenum and tungsten complex was COS ppm. (f) The chemical shifts of the R’ carbons change only slightly. Acknowledgment. We thank the donors of the Petroleum Research Fund, administered by the American Chemical Society, for the support of this research. We also thank the National Science Foundation for providing the funds for a tungsten probehead and Prof. J. H . Enemark for helpful discussions. M.M. thanks Grinnell College for a Harris Fellowship.